Biochar Adsorbents for Arsenic Removal from Water Environment: A Review
Arsenic intake can cause human health disorders to the lungs, urinary tract, kidney, liver, hyper-pigmentation, muscles, neurological and even cancer. Biochar is potent, economical and ecologically sound adsorbents for water purification. After surface modifications, adsorption capacity of biochar s...
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| Published in | Bulletin of environmental contamination and toxicology Vol. 108; no. 4; pp. 616 - 628 |
|---|---|
| Main Authors | , , , , |
| Format | Journal Article |
| Language | English |
| Published |
New York
Springer US
01.04.2022
Springer Nature B.V |
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| Online Access | Get full text |
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| Abstract | Arsenic intake can cause human health disorders to the lungs, urinary tract, kidney, liver, hyper-pigmentation, muscles, neurological and even cancer. Biochar is potent, economical and ecologically sound adsorbents for water purification. After surface modifications, adsorption capacity of biochar significantly increased due to high porosity and reactivity. Adsorption capacities of the biochar derived from the municipal solid waste and KOH mixed municipal solid waste were increased from 24.49 and 30.98 mg/g for arsenic adsorption. Complex formation, electrostatic behavior and ion exchange are important mechanisms for arsenic adsorption. Organic arsenic removal using biochar is a major challenge. Hence, more innovative research should be conducted to achieve one of the 17 sustainable development goals of the United Nations i.e. “
providing safe drinking water for all
”. This review is focused on the arsenic removal from water using pristine and modified biochar adsorbents. Recent advances in production methods of biochar adsorbents and mechanisms of arsenic removal from water are also illustrated. |
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| AbstractList | Arsenic intake can cause human health disorders to the lungs, urinary tract, kidney, liver, hyper-pigmentation, muscles, neurological and even cancer. Biochar is potent, economical and ecologically sound adsorbents for water purification. After surface modifications, adsorption capacity of biochar significantly increased due to high porosity and reactivity. Adsorption capacities of the biochar derived from the municipal solid waste and KOH mixed municipal solid waste were increased from 24.49 and 30.98 mg/g for arsenic adsorption. Complex formation, electrostatic behavior and ion exchange are important mechanisms for arsenic adsorption. Organic arsenic removal using biochar is a major challenge. Hence, more innovative research should be conducted to achieve one of the 17 sustainable development goals of the United Nations i.e. “
providing safe drinking water for all
”. This review is focused on the arsenic removal from water using pristine and modified biochar adsorbents. Recent advances in production methods of biochar adsorbents and mechanisms of arsenic removal from water are also illustrated. Arsenic intake can cause human health disorders to the lungs, urinary tract, kidney, liver, hyper-pigmentation, muscles, neurological and even cancer. Biochar is potent, economical and ecologically sound adsorbents for water purification. After surface modifications, adsorption capacity of biochar significantly increased due to high porosity and reactivity. Adsorption capacities of the biochar derived from the municipal solid waste and KOH mixed municipal solid waste were increased from 24.49 and 30.98 mg/g for arsenic adsorption. Complex formation, electrostatic behavior and ion exchange are important mechanisms for arsenic adsorption. Organic arsenic removal using biochar is a major challenge. Hence, more innovative research should be conducted to achieve one of the 17 sustainable development goals of the United Nations i.e. "providing safe drinking water for all". This review is focused on the arsenic removal from water using pristine and modified biochar adsorbents. Recent advances in production methods of biochar adsorbents and mechanisms of arsenic removal from water are also illustrated. Arsenic intake can cause human health disorders to the lungs, urinary tract, kidney, liver, hyper-pigmentation, muscles, neurological and even cancer. Biochar is potent, economical and ecologically sound adsorbents for water purification. After surface modifications, adsorption capacity of biochar significantly increased due to high porosity and reactivity. Adsorption capacities of the biochar derived from the municipal solid waste and KOH mixed municipal solid waste were increased from 24.49 and 30.98 mg/g for arsenic adsorption. Complex formation, electrostatic behavior and ion exchange are important mechanisms for arsenic adsorption. Organic arsenic removal using biochar is a major challenge. Hence, more innovative research should be conducted to achieve one of the 17 sustainable development goals of the United Nations i.e. “providing safe drinking water for all”. This review is focused on the arsenic removal from water using pristine and modified biochar adsorbents. Recent advances in production methods of biochar adsorbents and mechanisms of arsenic removal from water are also illustrated. Arsenic intake can cause human health disorders to the lungs, urinary tract, kidney, liver, hyper-pigmentation, muscles, neurological and even cancer. Biochar is potent, economical and ecologically sound adsorbents for water purification. After surface modifications, adsorption capacity of biochar significantly increased due to high porosity and reactivity. Adsorption capacities of the biochar derived from the municipal solid waste and KOH mixed municipal solid waste were increased from 24.49 and 30.98 mg/g for arsenic adsorption. Complex formation, electrostatic behavior and ion exchange are important mechanisms for arsenic adsorption. Organic arsenic removal using biochar is a major challenge. Hence, more innovative research should be conducted to achieve one of the 17 sustainable development goals of the United Nations i.e. "providing safe drinking water for all". This review is focused on the arsenic removal from water using pristine and modified biochar adsorbents. Recent advances in production methods of biochar adsorbents and mechanisms of arsenic removal from water are also illustrated.Arsenic intake can cause human health disorders to the lungs, urinary tract, kidney, liver, hyper-pigmentation, muscles, neurological and even cancer. Biochar is potent, economical and ecologically sound adsorbents for water purification. After surface modifications, adsorption capacity of biochar significantly increased due to high porosity and reactivity. Adsorption capacities of the biochar derived from the municipal solid waste and KOH mixed municipal solid waste were increased from 24.49 and 30.98 mg/g for arsenic adsorption. Complex formation, electrostatic behavior and ion exchange are important mechanisms for arsenic adsorption. Organic arsenic removal using biochar is a major challenge. Hence, more innovative research should be conducted to achieve one of the 17 sustainable development goals of the United Nations i.e. "providing safe drinking water for all". This review is focused on the arsenic removal from water using pristine and modified biochar adsorbents. Recent advances in production methods of biochar adsorbents and mechanisms of arsenic removal from water are also illustrated. |
| Author | Singh, Nirankar Izah, Sylvester Chibueze Singh, Prabhat Kumar Pham, Tien Duc Srivastav, Arun Lal |
| Author_xml | – sequence: 1 givenname: Arun Lal orcidid: 0000-0003-0238-7395 surname: Srivastav fullname: Srivastav, Arun Lal email: arun.srivastav@chitkarauniversity.edu.in, arunitbhu2009@gmail.com organization: Chitkara University School of Engineering and Technology, Chitkara University – sequence: 2 givenname: Tien Duc surname: Pham fullname: Pham, Tien Duc email: tienducpham@hus.edu.vn organization: Faculty of Chemistry, University of Science, Vietnam National University – sequence: 3 givenname: Sylvester Chibueze surname: Izah fullname: Izah, Sylvester Chibueze organization: Department of Microbiology, Faculty of Science, Bayelsa Medical University – sequence: 4 givenname: Nirankar surname: Singh fullname: Singh, Nirankar organization: Department of Chemistry, Maharishi Markandeshwar (Deemed to be University) – sequence: 5 givenname: Prabhat Kumar surname: Singh fullname: Singh, Prabhat Kumar organization: Department of Civil Engineering, Indian Institute of Technology (BHU) |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/34536097$$D View this record in MEDLINE/PubMed |
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| Keywords | Pyrolysis Modified biochar Biochar adsorbents Biochar production Arsenic removal mechanism |
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| Snippet | Arsenic intake can cause human health disorders to the lungs, urinary tract, kidney, liver, hyper-pigmentation, muscles, neurological and even cancer. Biochar... |
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| SubjectTerms | Adsorbents Adsorption Aquatic Pollution Arsenic Arsenic removal biochar Charcoal Complex formation Drinking water Earth and Environmental Science Ecotoxicology Environment Environmental Chemistry Environmental Health Focused Review human health hyperpigmentation Ion exchange kidneys liver Municipal solid waste Municipal waste management Muscles Pigmentation Pollutant removal Pollution Porosity Production methods Soil Science & Conservation Solid waste management Sustainable development toxicology Urinary tract Waste Water Technology Water Management Water Pollution Control Water purification |
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| Title | Biochar Adsorbents for Arsenic Removal from Water Environment: A Review |
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